Predicting materials properties without crystal structure: Deep representation learning from stoichiometry
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Machine learning can accelerate materials discovery by accurately predicting materials properties with low computational cost. However, the model inputs remain a key stumbling block: current methods typically use hand-engineered descriptors constructed from knowledge of either the full crystal structure -- applicable only to materials with experimentally measured structures as crystal structure prediction is computationally expensive -- or the stoichiometry. We develop a machine learning approach that takes only the stoichiometry as input and automatically learns the appropriate and systematically improvable descriptors from data. Our key insight is to treat the stoichiometric formula as a dense weighted graph between elements. Compared to the state of the art, our approach achieves lower error on a plethora of challenging material properties. Moreover, our model can estimate its own uncertainty as well as transfer its learnt representation, extracting useful information from a cognate data-abundant task to deploy on a data-poor task.
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